DE102005043879B4 - Method and communication arrangement for transmitting data frames of a time-slot-oriented communication network via a passive optical communication network or PON - Google Patents

Abstract

Method for transmitting data frames (E1, DS1) of a time-slot-oriented communication network via a passive optical communication network or PON,
characterized,
a transmission frame (FR) comprises a plurality of subframes (UR1 ... 4),
each of the subframes (UR1 ... 4) comprises at least a part of a data frame (E1, DS1) of the timeslot-oriented communication network, and
in that at least some of the subframes (UR1 ... 4) comprise synchronous information (C1_1 ... C1_3, C2_1 ... C2_3, S1, 2) in that the transmission frame (FR) is connected by means of a plurality of PON-specific data packets via the optical Communication network is transmitted
in which
the synchronous information (C1_1 ... C1_3, C2_1 ... C2_3, S1, 2) stuffing information (S1, 2), which can be assigned variably, as well as stuffing control information (C1_1 ... C1_3, C2_1) characterizing the current allocation of the stuffing information (S1, 2) ... C2_3),
wherein the stuffing information is transmitted in at least one stuffing bit (S1, 2) and in less than eight stuffing bits (S1, 2).

Description

The transmission of time-slot oriented information (TDM Transmission) over G-PON communication networks (Gigabit Capable Passive Optical Network) is described in standard ITU-T G.984.3 Appendix I. According to the method described there (transport of user traffic over GEM channels), the regeneration of the E1 / DS1 clock takes place by means of adaptive clock recovery by using "byte stuffing". Generally, adaptive clock recovery is not recommended if the jitter and wander requirements (jitter with very long phase changes) in G.823 / G.824 must be met. In the method described in Appendix I for the transmission of time-slot-oriented information, user data frames are transmitted in time intervals of 125 μs, the time base (timing base) required for this purpose is determined by the network reference clock (NTR) of the network reference clock G-PON derived. A user data frame contains an integer number of data bytes. The length of the user data frame is variable; this depends on the frequency offset between the current TDM clock frequency and the NTR clock frequency.

For the hypothetical case of E1 data transmission (256 bits / 125 μs) with identical TDM and NTR clocks, the data frames to be transmitted have a predetermined data volume of 32 bytes. In the event that the TDM clock is faster than the NTR clock, a data frame with 33 bytes of data volume or payload is transmitted at certain times. In the event that the TDM clock is slower than the NTR clock, at certain times a data frame with a smaller data volume of 31 bytes is transmitted - "byte stuffing". The respectively different length of the data frames to be transmitted is identified according to G.984 by the PLI value (payload length indicator) in the GEM frame header. On the receive side, the incoming data frames are stored in a FIFO buffer. The TDM clock recovery is ensured by a local oscillator, which is controlled by the respective level of the FIFO. The nominal oscillator frequency is derived from the NTR clock. If the transmit-side TDM clock is faster than the NTR clock, the level of the FIFO is permanently increased. To compensate for this or compensate for the frequency of the local oscillator is increased, which has a mean constant FIFO level result.

A substantially similar situation arises for the transmission of DS1 data streams (193 bits / 125 μs). This is followed by seven transmitted data frames with a respective data volume of 24 bytes, a data frame with a data size of 25 bytes. The time interval between two transmitted 25-byte data frames depends on the current clock deviation.

The stuffing method described above is known as "byte stuffing" with adaptive clock recovery. A disadvantage is caused by 8-bit phase jumps and long stuffing intervals in "byte stuffing" a high wander.

Byte Stuffing with adaptive clock recovery is currently also used for TDM line emulations in ATM networks based on AAL1. Also, only bad jitter properties are achieved.

Currently, no transmission method is known for the transmission of time-slot-oriented information via G-PON, which fulfills the jitter and wander requirements according to G.823 / G.824. Within the FSAN standardization group, the introduction of the already mentioned ATM-based AAL1 principles of E1 / DS1 line emulation over ATM for use in G-PON is discussed. In addition, if the possibilities of SRTS (Synchronous Residual Time Stamp) are implemented, a satisfactory jitter performance can be achieved. The introduction of ATM-compliant AAL1 principles, however, is associated with increased technical and thus increased economic outlay. Furthermore, a line emulation is generally associated with transmission delays, which is not accepted by users, especially with regard to the transmission of time-critical information.

From the US 2003/0020991 A1 For example, automatic bandwidth adjustment in a passive optical network is known. A rented channel can contain TDM data. In an overhead of the channel is, inter alia, a two-byte payload length specification, which allow a variable payload in connection with padding bytes in the payload.

From the EP 1 365 548 A1 and from the WO 02/45308 For example, methods for encapsulating variable length packets are known, with reference to byte boundaries.

The invention has for its object to improve the transmission of time-slot-oriented information about G-PONs. The object is achieved on the basis of a method according to the preamble of patent claim 1 by its characterizing feature and by a communication arrangement according to claim 9.

The essential aspect of the inventive method for transmitting data frames of a timeslot-oriented Communication network via a passive optical communication network or PON is that a transmission frame FR) comprises a plurality of subframes, each of the subframes comprises at least a portion of a data frame of the time-slot-oriented communication network and at least a portion of the subframe comprises synchronous information. The transmission frame is transmitted by means of several PON-specific data packets via the optical communication network.

The main advantage of the method according to the invention is that, compared with conventional clock recovery methods used in PON, a significant improvement in the clock recovery in terms of jitter and wander properties is achieved.

In the following, the method according to the invention is explained in more detail with reference to several drawings. Showing:

1 an exemplary embodiment of the structure of the transmission frame for the transmission of E1 data streams via G-PON in the context of the inventive method

2 an exemplary embodiment of the structure of the transmission frame for the transmission of DS1 data streams via G-PON in the context of the inventive method

1 shows in a block diagram an exemplary embodiment of the structure of a transmission frame FR for the transmission of E1 data streams or E1 data frames via G-PON. With the help of in 1 shown frame structure FR E1 payload representing E1PL payload is inserted or mapped in GEM frames of a G-PON communication network. The illustrated transmission frame FR comprises four subframes UR1... 4 each having 33 bytes of data volume. Each subframe UR1... 4 comprises 8-bit overhead information OH and a user data portion comprising 32 bytes of data in which the respective 32-byte data volume E1 payload E1PL of an E1 data frame is inserted.

To compensate for clock deviations, the fourth subframe UR4 comprises two variably assignable bit positions or stuffing bits S1, S2 (also referred to as stuffing possibilities) representing part of synchronous information, the first stuffing bit S1 being part of the OH overhead and the second stuffing bit S2 being part of the Payload E1PL is. Each of the subframes UR1 ... 4 has a time extension of 125 μs, wherein the entire transmission frame FR has a time extension of 500 μs. According to one embodiment variant of the method according to the invention, each subframe UR1... 4 is transmitted separately by means of a PON-specific data packet via the optical communication network. PON-specific data packets are formed at G-PON by T-CONTs data units (transmission containers). At least one GEM user data frame is transmitted via the G-PON in a T-CONT. In the OH overhead of each subframe UR1... 4, a sequence number SN is in each case arranged which can assume values from 0 to 3. According to 1 the stuffing bits S1, S2 are arranged in the fourth subframe UR4 with the sequence number SN = 03, ie with the aid of the sequence number SN the position of the stuffing bits S1, 2 within the transmission frame FR can be referenced.

The two stuffing bits S1, 2 can be used as stuffing or information bits (variable stuff bits) depending on clock deviations between TDM and NTR clock. Information about the current use or assignment of these stuffing bits are given by the stuffing control information or bits C1_1... C2_3 respectively arranged in the second, third and fourth subframes UR2, 3, 4, which likewise form part of the synchronous information C1_1. .C2_3, S1, S2 form. Each of the subframes UR2, 3, 4 contains a first and a second stuff control bit C1, C2 in the overhead OH, the value C = 0 the use of the associated stuffing bit S as data bit and the value C = 1 the use of the stuffing bit S as actual stuff bit or dummy bit. To increase the reliability of the error, the two stuff control bits C1, C2 are arranged in 3 subframes UR2... 4 of the transmission frame FR in parallel, the respective associated stuff control bits - here C1_1 ... C1_3 and C2_1 ... C2_3 - forming a sequence. The majority of the bits arranged in a sequence decide on the actual use of the associated stuff bit S1, 2.

This in 1 The "bit stuffing" shown enables the variable transmission of either 1023, 1024 or 1025 payload bits within a 500 μs frame FR, which compensates for frequency deviations of up to ± 1000 ppm between the E1 TDM bit rate and the reference clock. The jitter caused thereby corresponds approximately to the jitter generated in the E1-mapping in SDH environments according to G.783, Tab. 15-3.

According to 1 are arranged in the overhead OH of each subframe UR1 ... 4 more stuffing information R, but their function is fixed in contrast to the variably assignable stuffing S1, 2 fixed as a stuffing bit.

2 shows in a further block diagram an exemplary embodiment of the structure of the transmission frame FR for the transmission of DS1 data streams or DS1 payload via G-PON. In contrast to 1 In each of the four subframes UR1... 4, a DS1 payload DS1PL comprising 24 bytes of data volume is transmitted in accordance with the DS1 frame structure. As another difference, both stuffing bits S1, S2 are part of the overhead OH of the fourth subframe UR4. Incidentally, the same remarks apply as to 1 ,

Usually, a plurality of decentralized communication devices or ONUs (Optical Network Units) are connected via a PON to a central communication device or OLT Optical Line Termination. An ONU can have multiple E1 and / or DS1 interfaces. In such constellations, a transmission frame FR can be formed in each case according to an advantageous embodiment of the method according to the invention for each interface assigned to an ONU. In this case, subframes of different transmission frames can be multiplexed or mapped into a data packet or T-CONT of the G-PON in an ONU.

With the aid of the method according to the invention, the transmission characteristics for the transmission of timeslot-oriented information can be decisively improved in G-PON communication networks to the extent that the requirements for jitter and wander according to G.823 / G.824 are largely maintained.

It should be noted that, for carrying out the method according to the invention, the number of subframes UR arranged in a transmission frame FR and the number of stuffing control bits and stuffing bits can be chosen as desired.

Claims (8)

Method for transmitting data frames (E1, DS1) of a time-slot-oriented communication network via a passive optical communication network or PON, characterized in that a transmission frame (FR) comprises a plurality of subframes (UR1 ... 4) that each of the subframes (UR1 .. 4). .4) each comprises at least a part of a data frame (E1, DS1) of the time-slot-oriented communication network, and that at least a part of the subframes (UR1 ... 4) synchronous information (C1_1 ... C1_3, C2_1 ... C2_3, S1 , 2), in that the transmission frame (FR) is transmitted by means of a plurality of PON-specific data packets via the optical communication network, wherein the synchronous information (C1_1 ... C1_3, C2_1 ... C2_3, S1, 2) can be variably assigned stuffing information (S1 , 2) as well as the current allocation of the stuffing information (S1, 2) characterizing stuff control information (C1_1 ... C1_3, C2_1 ... C2_3), wherein the stuffing information in at least one stuffing bit (S1, 2) and in little it is transmitted as eight stuffing bits (S1, 2). A method according to claim 1, characterized in that in a subframe (UR4) of the transmission frame (FR) two variably assignable, the stuffing information representing stuffing bits (S1, 2) are arranged. A method according to claim 2, characterized in that in each case at least one of the subframes (UR1 ... 4) of the transmission frame (FR) 2 stuffing control bits (C1_1 ... C1_3, C2_1 ... C2_3) are arranged as Stopfkontrollinformationen. Method according to one of the preceding claims, characterized in that in each case a subframe (UR1 ... 4) of the transmission frame (FR) is inserted into a PON-specific data packet. Method according to one of the preceding claims, characterized in that the transmission frame (FR) comprises four subframes (UR1 ... 4). Method according to one of the preceding claims, characterized in that the data frame (E1, DS1) of the time-slot-oriented communication network is configured as E1 or DS1 data frame. Method according to one of the preceding claims, characterized in that the packet-oriented communication network as a G-PON, Gigabit-capable passive optical network according to the standard ITU-T 984 is configured. Communication arrangement configured for carrying out the method according to one of the preceding claims.

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